Adjustable riding toy with wave ride wheel

ABSTRACT

Adjustable riding toys are provided in both bicycle and tricycle forms. The tricycle and bicycle have at least one wave ride wheel allowing a rider to change between a smooth ride and an up and down ride. Both rear wheels on the tricycle are provided with synchronized wave ride wheels which create a side to side wobble of the riding toy. Methods of adjusting the bicycle and tricycle are also provided.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of application Ser. No.08/430,726, filed on Apr. 28, 1995, and a continuation-in-part ofapplication Ser. No. 29/035,039, filed Feb. 17, 1995, and acontinuation-in-part of application Ser. No. 29/034,324, filed Feb. 1,1995, now abandoned and a continuation-in-part of application Ser. No.29/033,934, filed Jan. 24, 1995, and now U.S. Pat. No. Des. 369,331, thedisclosures of which are hereby incorporated by reference.

BACKGROUND OF THE INVENTION

The present invention relates to children's riding toys and moreparticularly to an assembly for adjusting the riding toy. The height ofthe riding toy, the number of wheels on the riding toy, the position ofthe training wheels and the type of ride all adjust on one toy.

Wheeled riding toys of various configurations are known. However, manyaspects common to most riding toys have drawbacks.

Two-wheeled and three-wheeled riding toys are common. These two types ofriding toys require many different parts. Thus, the cost to manufacturetwo separate toys is made more expensive.

Generally, riding toys will have adjustable seat and handle bar heightsto accommodate people of various sizes. These adjustments allow oneriding toy to be used by the same child over a period of limited timeand limited growth. However, these adjustments only adjust to a certainpoint before a child can no longer comfortably ride the riding toy. Anew riding toy then must be purchased.

Riding toys allow mobility as a form of enjoyment, but rarely more.Children often resort to horns, spoke clackers or other decorations toadd enjoyment to riding a wheeled toy. New forms of riding enjoyment areconstantly sought.

Two-wheeled riding toys take more skill and balance to ride thanthree-wheeled riding toys. As a means to help beginning riders developthe needed balance, training wheels are often provided. Training wheelstypically consist of a bracket connected to the body of a riding toy,and a wheel connected to the bracket. However, these training wheelsrequire multiple parts which may be lost, especially when the trainingwheels are removed. Multiple parts also contribute to increased costs.

SUMMARY OF THE INVENTION

The preferred embodiments of the instant invention provide solutions toall of these problems. In one aspect, the invention is a wheeled ridingtoy with an adjustable height axle connection comprising a body with aseat thereon, one or more wheels rotatably attached to the body, amounting arm connected to the body, one wheel having an axle, and theone wheel being rotatably connected to the mounting arm, wherein themounting arm has at least two axle apertures, and the axle is disposedwithin one of the axle apertures.

In a second aspect, the invention is a wheeled riding toy having a bodycomprising a monolithic back end portion having a plurality ofpredetermined connection apertures, a rear wheel rotatably attached tothe back end portion, a from mounting arm pivotally connected to thebody with a steering mechanism connected thereto, a front wheelrotatably connected to the from mounting arm, and a training wheelassembly comprising a training wheel having a training wheel axleaperture, a training wheel axle operatively connected to the trainingwheel at the training wheel axle aperture, and the training wheel axlereleasably connected to one of the connection apertures.

In a third aspect, the invention is a wheeled riding toy having anengageable wave ride wheel comprising a body, a first rear wheelrotatably attached to the body, a front mounting arm pivotally connectedto the body with a steering mechanism connected thereto, a front wheelrotatably attached to the front mounting arm, and any one of the frontor first rear wheels comprising a wave ride wheel having a center and atleast two wheel axle apertures, at least one wheel axle aperture notbeing at the center of the wheel.

In a fourth aspect, the invention is a combination of four members,three of which fit together to form a bicycle and three of which fittogether to form a tricycle, the four members comprising a body having afirst and second body end; a front wheel rotatably connected to thefirst body end; a bicycle back end comprising at least one prong backend, each prong back end connectable to the second body end and a backend wheel rotatably connected to each prong back end; and a tricycleback end comprising at least one prong back end, each prong back endconnectable to the second body end and a first and second rear wheel,each rear wheel rotatably connected to each prong back end.

Through the use of the preferred interchangeable back ends,manufacturing costs are decreased. The parts for the body of the ridingtoy are the same no matter which back end is used.

The preferred embodiments also allow for a larger range of growth beforea new riding toy purchase is necessary. A height adjustment where anaxle connects to the riding toy is provided. The riding toy has multipleapertures to connect with an axle. By adjusting which aperture on theriding toy is used for the front axle, the distance from the pedals tothe handle bars is increased, allowing a larger person to use the ridingtoy.

The preferred embodiments also provide added enjoyment to riding.Multiple apertures in the wheels are provided, where at least oneaperture is not at the center of the wheel. By placing the axle throughthe off-center aperture, a wave ride, or up and down, effect is created.In a tricycle configuration, one rear wheel may be adjusted, or both, tocreate a side to side effect along with the up and down motion. Allowingadjustment from regular smooth rides to the wave ride maintains theclassic uses of the riding toy while providing an added aspect ofenjoyment.

The preferred embodiments also require fewer parts for the trainingwheels, avoiding lost parts. The training wheels connect right to thebody of the riding toy and may be adjusted upward, downward or removedto accommodate riders of various skill. These and other advantages ofthe invention, as well as the preferred embodiments, will be bestunderstood by reference to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a right side view of a bicycle adjustable riding toy;

FIG. 2 is a right side view of a tricycle adjustable riding toy;

FIG. 3 is a side view of a wheel assembly using spacer quarters used onthe tricycle adjustable riding toy of FIG. 2;

FIG. 4 is a cross section view of a wheel assembly of FIG. 3 taken alongline 4--4;

FIG. 5 is an elevational side view of a spacer quarter used in the wheelassembly of FIG. 3;

FIG. 6 is an elevational end view of the spacer quarter of FIG. 5;

FIG. 7 is an exploded right from perspective view of the bicycleadjustable riding toy of FIG. 1;

FIG. 8 is an exploded right front perspective view of the tricycleadjustable riding toy of FIG. 2;

FIG. 9 is a left side view of another embodiment of a bicycle adjustableriding toy;

FIG. 10 is a rear view of the tricycle adjustable riding toy of FIG. 2with spacers between the wheels; and

FIG. 11 is a rear view of the tricycle adjustable riding toy of FIG. 2with the rear wheels placed next to one another.

DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EMBODIMENTS

Referring now to the drawings, two preferred embodiments of riding toysare illustrated and generally indicated at 12 and 14 in FIGS. 1 and 2.FIGS. 1 and 9 depict the use of this invention on a bicycle 12 and 13,and FIG. 2 depicts the use of this invention on a tricycle 14. Referringto FIGS. 1 and 7, the bicycle 12 embodiment of the present inventionwill be used to illustrate one preferred embodiment. However, manyaspects of the invention may be adapted for use on riding toys with anynumber of wheels.

The bicycle 12 comprises a body 16, a bicycle back end 18, a front wheel20 and a rear wheel 22. The construction is preferably from suitablemolded plastic material and is generally known in the industry. However,the present invention may be constructed from any other suitablematerials, such as various metals. The body 16 is connected to thebicycle back end 18. The connection will be addressed in more detailbelow. The front and rear wheels 20 and 22 are rotatably connected tothe body 16 and bicycle back end 18, respectively, to allow the bicycle12 to roll. A seat 24 for holding the body of a rider is preferablymolded into the body 16, but may be attached as a separate piece.

The body 16 comprises a support 26, a steering mechanism 28, and a frontmounting arm 30. The front mounting arm 30 is pivotally connected to thebody front end 32. Referring to FIG. 7, the steering mechanism 28connects to the front mounting arm 30, preferably with a bolt 29 and nut31, to allow a rider to steer the bicycle 12. The front mounting arm 30comprises one or more prong arms 34. Preferably two prong arms 34 areused for maximum stability. The front wheel 20 rotatably connects to theprong arms 34 and is preferably located between the prong arms 34.

The front wheel 20 rotatably connects to the prong arms 34 by a frontaxle 36. The front axle 36 is preferably made out of a suitable metal. Apedal 38 is connected to each end of the front axle 36 by a washer withserrations for gripping the front axle 36. The washer keeps the pedal 38from sliding off of the front axle 36. The front axle 36 is shaped as iscommon to allow circular motion from a rider's feet to create rotationof the front wheel 20.

The front wheel 20 and rear wheel 22 each comprise an outer wheel 40having a holder aperture 41 and two sides, and a spacer, designatedgenerally at 42. For the front wheel 20, the spacer 42 comprises fourspacer quarters 44. Referring to FIG. 3 and as discussed in more detailbelow, the four spacer quarters 44 are placed together to create wheelaxle apertures 46 for receiving the front axle 36. Referring again toFIG. 1, the front wheel 20 is rotatably connected to the prong arms 34by placing the front axle 36 through an axle aperture 52 located on eachprong arm 34. The front axle 36 is allowed to rotatably move within theaxle aperture 52.

An adjustable height axle connection is shown generally in FIGS. 7 at54. The prong arms 34 comprise a first prong piece 56 and a second prongpiece 58. The first prong piece 56 of each prong arm 34 has multiplefirst edge cut outs 60, which are preferably half-circular in shape. Inthe preferred embodiment, there are two first edge cut outs 60, oneplaced above the other in reference to the ground. However, there may bemore than two first edge cut-outs 60 and the first edge cut outs 60 maybe placed in a horizontal relation to each other.

Preferably, the second prong piece 58 also has two second edge cut-outs62. As long as the first prong piece 56 has first edge cut-outs 60, thesecond prong piece 58 does not have to have second edge cut-outs 60 andvice versa. Alternatively, the first prong piece 56 may have one firstedge cut-out 60 as long as the second prong piece 58 has a second edgecut-out 62 which does not align with the first edge cut out 60 when thefirst prong piece 56 is mounted to the second prong piece 58, asdiscussed in more detail below. It is noted that one axle aperture 52which creates two separate areas for holding the front axle 36 is withinthe scope of the present invention by effectively creating two axleapertures 52.

Referring to FIG. 1, when the first prong piece 56 is mounted to thesecond prong piece 58, the two first edge cut-outs 60 preferably alignwith the two second edge cut-outs 62 to form two axle apertures 52.Preferably, two apertures 57 are molded into the first prong piece 56for accepting at least one screw, and preferably two screws 64, suitablefor mounting in plastic. The screws 64 mount the first prong piece 56 tothe second prong piece 58. The second prong piece 58 has molded plasticformed to be suitable for securely holding the screws 64. Furthermore,straps, clamps or other mounting means may be used to mount the firstprong piece 56 to the second prong piece 58.

Referring to FIG. 7, to adjust the height of the riding toy 10, firstthe screws 64 are removed from the prong arms 34. Then, the first prongpiece 56 is separated from the second prong piece 58. The front axle 36is taken from a position alongside one of the second edge cut-outs 62and placed in a position along side another second edge cut-out 62. Thefirst prong piece 56 is then mounted to the second prong piece 58 withthe screws 64. The front axle 36 is now located in a different axleaperture 52. By placing the axle 36 in a different axle aperture 52, thedistance between the steering mechanism 28 and the pedals 38 may beincreased or decreased, allowing different sized people to ride theriding toy 10. The adjustable height axle connection 54 may alsoincrease or decrease the distance from the seat 24 to the ground. Theadjustable height axle connection 54 may also be used on the rear wheel22, but that embodiment is not preferred.

The engageable wave ride wheel is shown generally in FIGS. 3, 4 and 7 at66. Referring to FIGS. 3, 4, 5 and 6, for the front wheel 20, there arefour spacer quarters 44 which comprise the spacer 42. Two spacerquarters 44 will form a spacer half 68, when the spacer quarter fiatsides 70 are placed adjacent to each other as shown in FIG. 3.Preferably the spacer half 68 will be circular in shape on one end 43and rectangular on the other end 45 as shown in FIGS. 5 and 7. Referringto FIGS. 4 and 7, the rectangular end 45 of the spacer half 68 fitswithin the rectangular holder aperture 41 of the outer wheel 40 so thatas the spacer half 68 rotates, the outer wheel 40 also rotates. Twospacer halves 68 are placed within the holder aperture 41 of the outerwheel 40. Each spacer half 68 is positioned from opposite sides of theouter wheel 40 into retention grooves 72.

Referring to FIGS. 3, 6 and 7, each spacer quarter 44 has at least twospacer cut-outs 74. The spacer cut-outs 74 are located on the spacerquarter's flat side 70. When the spacer quarters fiat sides 70 areplaced next to each other to create a spacer half 68, the spacercut-outs 74, will align to create at least two wheel axle apertures 46.Preferably, one wheel axle aperture 46 is located at the center of thespacer half 68 with two other wheel axle apertures 46 located onopposite sides of center. Each wheel axle aperture 46 preferably iscircular in shape with a linear notch 76 for functionally accepting aswedge 48 on the from axle 36. As the front axle 36 rotates, the swedges48 engage the linear notch 76 forcing the spacer 42 and outer wheel 40to also rotate.

When the front axle 36 is placed through the wheel axle aperture 46located at the center of the front wheel 20, a level ride occurs.However, when the front axle 36 is placed through a wheel axle aperture46 located in a position other than the center of the front wheel 20, anup and down motion in the riding toy 10 is created as the riding toy 10moves.

To adjust the engageable wave ride wheel 66, the front axle 36 isremoved from one wheel axle aperture 46 and placed in another wheel axleaperture 46. On the front wheel 20, which uses spacer quarters 44,adjusting the engageable wave ride wheel 66 requires removing the frontwheel 20 and front axle 36 from between the prong arms 34 as discussedabove. A spacer quarter 44 is removed from each side of the outer wheel40. The front axle 36 is removed from a position adjacent one spacercut-out 74 on each spacer quarter 44 remaining in the outer wheel 40.The front axle 36 is then placed in a position adjacent a differentspacer cut-out 74. The front axle 36 is preferably positioned in asimilar manner for each spacer half 68 on the front wheel 20. Theremoved spacer quarters 44 are then placed adjacent the spacer quarters44 still within the outer wheel 40, creating the wheel axle apertures46. The front wheel 20 and front axle 36 are then connected to thebicycle 12 as discussed above. For a bicycle 12 meant to be used withtraining wheels 116, the wave ride wheel is not used on the rear wheel22 to avoid toppling a rider.

Referring now to FIG. 7, the predetermined frame supported adjustableheight training wheels are generally designated at 100. Thepredetermined frame supported adjustable height training wheels 100 areshown on a bicycle 12, but may be used on a riding toy with any numberof wheels.

The predetermined frame supported adjustable height training wheels 100are preferably located one on each side of the bicycle 12. However, onlyone predetermined frame supported adjustable height training wheel 100is required. Furthermore, the predetermined frame supported adjustableheight training wheel(s) 100 are preferably but not necessarily placednear the rear wheel 22.

The rear wheel 22 is rotatably connected to the bicycle back end 18 ofthe bicycle 12 by a bicycle back axle 78. The bicycle back end 18 may bepart of a continuous support 26 of the bicycle 12. Preferably, thebicycle back end 18 comprises a left prong back end 102 and a rightprong back end 104, with the rear wheel 22 held in place by the bicycleback axle 78 between the left and right prong back ends 102 and 104. Thebicycle back axle 78 is placed through the axle aperture 52 on the leftand right back ends 102 and 104, and through the wheel axle aperture 46on the bicycle rear wheel spacer halves 69. The bicycle back axle 78 isheld in place by two snap-fit axle caps 90 which snap-fit onto theswedges 48 on each end of the bicycle back axle 78.

For purposes of the preferred embodiment of the predetermined framesupported adjustable height training wheels 100, the rest of thediscussion will deal with only the right predetermined frame supportedadjustable height training wheel 100. It is understood that the leftpredetermined frame supported adjustable height training wheel 100 isthe same. The bicycle back end 18 has upper and lower connectionapertures 110 and 112. The upper and lower connection apertures 110 and112 are located on the monolithic right prong back end 104. Themonolithic right prong back end 104 is, for example, one uniform blowmolded part. There are no separate brackets for connection of thetraining wheel assembly, generally noted at 114, to the bicycle back end18. The upper connection aperture 110 is located at least partiallyabove the lower connection aperture 112. Preferably, the upperconnection aperture 110 is placed slightly forward of the lowerconnection aperture 112 for structural strength, but may be placedslightly rearward.

The training wheel assembly, generally noted at 114, comprises atraining wheel 116 and a training wheel axle 118. The training wheel 116has a centrally located training wheel axle aperture 120 for rotatablyconnecting to the training wheel axle 118. The training wheel axle 118comprises a training wheel axle head 122, shaft 124 and threaded end126. The training wheel axle 118 is slid through the training wheel axleaperture 120 until the training wheel axle head 122 prevents any furthersliding. The training wheel axle threaded end 126 is then placed ineither the upper or lower connection apertures 110 or 112. Pressed intothe upper and lower connection apertures 110 and 112 on the side of theright prong back end 104 opposite the training wheel 116 is a metalt-nut assembly 128. The training wheel axle threaded end 126 is threadedinto a t-nut assembly 128. The t-nut assembly 128 prevents overtightening the training wheel axle head 122 against the training wheel116. Other attachments which allow rotation of the training wheel buthold the training wheel axle 118 in place may be used, like a cotter pinassembly.

Preferably, the lower connection aperture 112 is placed above the lowestpart of the rear wheel 22 by a distance approximately equal to theradius of the training wheel 116. The upper connection aperture 110 willbe at a position slightly higher than the lower connection aperture 112.By connecting the training wheel axle 120 to the lower connectionaperture 112, maximum stability from side to side tilting of the bicycle12 is achieved. When the training wheel axle 118 is connected to theupper connection aperture 110, some side to side tilting of the bicycle12 is allowed, but the training wheels 116 will still prevent thebicycle 12 from tipping over. By disconnecting the training wheel axle118 from the bicycle back end 18, the bicycle 12 may be used without anyadded stability from training wheels 116.

The training wheel axle 118 is adjusted from the lower connectionaperture 112 to the upper connection aperture 110, or vise versa, byfirst unthreading the training wheel axle threaded end 126 from thet-nut assembly 128. The training wheel axle 118 is then placed withinthe upper or lower connection aperture 110 or 112 and threaded into thet-nut assembly 128. To remove the training wheel assembly 114, thetraining wheel axle 118 is unthreaded from the t-nut assembly 128.

Referring to FIG. 9, a second bicycle 13 is shown. The second bicycleincorporates the adjustable height axle connection 54 described above.

Referring to FIG. 2 and 8, the tricycle 14 incorporates the adjustableheight axle connection 54 described above. The tricycle 14 alsoincorporates the engageable wave ride wheel 66 described above for thefront wheel 20.

Referring now to FIG. 8, the engageable wave ride wheel 66 is used oneach rear wheel 22 of the tricycle 14. A different preferred embodimentis used for the engageable wave ride wheel 66 as used on the rear wheels22. Only one rear wheel 22 on the tricycle 14 will be discussed, but itis understood that the two rear wheels 22 are preferably identical.Where the engageable wave ride wheel 66 is used on the rear wheel 22,the spacer 42 preferably comprises two spacer halves 68. The spacerhalves 68 are placed within the outer wheel 40 in retention grooves 72.Each spacer half 68 is placed on a different side of the outer wheel 40.

Each spacer half 68 preferably has three wheel axle apertures 46, butmay have only one wheel axle aperture 46 where a wave ride wheel is notdesired, like on the rear wheel 22 of the bicycle 12. Two wheel axleapertures 46 may also suffice to create an engageable wave ride wheel66. One wheel axle aperture 46 is preferably located at the center ofthe assembled rear wheel 22. Referring to FIGS. 8, the tricycle backaxle 88 is placed through a wheel axle aperture 46 and an axle apertures52. The tricycle back axle 88 is held in place with snap-fit axle caps90 which connect to swedges 48. Further, other means may be available tohold the tricycle back axle 88 in place such as a nut and bolt.

To adjust the engageable wave ride wheel 66, the axle cap 90 is removedfrom the tricycle back axle 88. The tricycle back axle 88 is removedfrom one wheel axle aperture 46 and placed back through a differentwheel axle aperture 46. The axle cap 90 is then reattached to thetricycle back axle 78 or 88.

Referring to FIG. 8, the engageable wave ride wheel 66 may be adjustedon either or both rear wheels 22 on a tricycle 14. The tricycle backaxle 88 has multiple swedges 48. The swedges 48 are placed in a linearnotch 76 on each spacer half 68, creating synchronous rotation of therear wheels 22. Each spacer half 68 has three wheel axle apertures 46,one located at the center of the rear wheel 22 and the other two onopposite sides of the wheel axle aperture 46 at the center of the rearwheel 22 as shown in FIG. 8. By adjusting the engageable wave ride wheel66 on one rear wheel 22 to one off-center wheel axle aperture 46 andadjusting the tricycle back axle 88 on the other rear wheel 22 to thewheel axle aperture 46 on the different side of center, synchronousrotation of the rear wheels 22 creams a side to side wobble of thetricycle back end 86. By adjusting the tricycle back axle 88 on bothrear wheels 22 to wheel axle apertures 46 on the same side of the rearwheel's 22 center, the side to side effect is eliminated but the up anddown motion is maintained.

Referring to FIGS. 10 and 11, a method of changing a tricycle 14 into abicycle 12 is shown. By removing the axle cap 90, the tricycle back axle88 can then be removed. The rear wheels 22 are placed between the leftand right prong back ends 202 and 204. Tricycle spacers 144 are placedon the outside of the left and right prong back ends 202 and 204. Thetricycle back axle 88 is then replaced, and the axle cap 90 is snappedonto the tricycle back axle 88.

Referring to FIGS. 7 and 8, to manufacture a bicycle 12 or tricycle 14less expensively, interchangeable back ends, generally designated at130, are used. The body 16 has two interchange apertures 132, on thebody back end 33. Preferably, between the interchange apertures 132 andon both sides of the body 16 is a protrusion 134.

A bicycle back end 18 preferably comprises a rear wheel 22 between aleft and right prong back end 102 and 104. The tricycle back end 86preferably comprises two rear wheels 22, each placed on the outside of aleft and right prong back end 202 and 204 and two tricycle spacers 144positioned between the left and right prong back ends 202 and 204.

Back end apertures 136 are located on the end of the left and rightprong back ends 102 and 104, and 202 and 204, opposite the rear wheel(s)22. Between the back end apertures 136 on both the left and right prongback end 102 and 104, and 202 and 204, is a depression 138 shaped to fitaround the protrusion 134. Each protrusion 134 will fit within eachdepression 138, and the back end apertures 136 will align with eachinterchange aperture 132. The protrusion 134 is designed to snap-fitinto the depression 138. Both the protrusion 134 and the depression 138are preferably not circular in shape to add structural support to theriding toy 10.

Two interchange bolts 140 fit through the back end apertures 136 on boththe left and right prong back ends 102 and 104, and 202 and 204, and theinterchange apertures 132. Two interchange nuts 142 are threaded ontothe interchange bolts 140. The interchange bolts 140 and each protrusion134 within a depressions 138 hold the interchangeable back end 130 tothe body 16 and prevent any movement of the interchangeable back end 130counter to the body 16. Other devices, such as a clamp, may fasten theinterchangeable back end 130 to the body 16.

Interchangeable back ends 130 allow the same front wheel 20 and body 16to be used on both a tricycle 14 or bicycle 12. The front wheel 20 andthe rear wheels 22 use the same outer wheel 40. To manufacture a bicycle12, the bicycle back end 18 is combined with a body 16 and front wheel20. To manufacture a tricycle 14, the tricycle back end 86 is combinedwith a body 16 and a front wheel 20. Furthermore, a bicycle back end 18may even be changed to a tricycle back end 86 or vise versa.

It is the following claims, including all equivalents, which areintended to define the scope of this invention.

We claim:
 1. A wheeled riding toy having an engageable wave ride wheelcomprising:a) a body; b) a first rear wheel rotatably attached to thebody; c) a front mounting arm pivotally connected to the body with asteering mechanism connected thereto; d) a front wheel rotatablyattached to the front mounting arm; and e) at least one of the front orfirst rear wheels comprising a wave ride wheel having an outer wheel anda spacer, the wave ride wheel having a center and at least two wheelaxle apertures, at least one of said wheel axle apertures not being atthe center of the wheel, the outer wheel having a holder aperture forreceiving the spacer, and the spacer comprising the wheel axleapertures.
 2. The wheel riding toy having an engageable wave ride wheelof claim 1, wherein the at least two wheel axle apertures comprise afirst, second and third wheel axle aperture, the second and third wheelaxle apertures not being at the center of the wheel.
 3. The wheeledriding toy having an engageable wave ride wheel of claim 1, wherein;a)the spacer comprises a first and a second spacer half; b) the wave ridewheel has a first and second wheel side; c) the holder aperture is onthe first and second wheel side; and d) the first and second spacerhalves are received by the holder aperture on the first and second wheelsides respectively.
 4. The wheeled riding toy having an engageable waveride wheel of claim 3, wherein the front wheel is the wave ride wheel.5. The wheeled riding toy having an engageable wave ride wheel of claim4, wherein the first rear wheel also is a wave ride wheel having anouter wheel and a spacer, the wheel having a center and at least twowheel axle apertures, at least one of said wheel axle apertures notbeing at the center of the wheel, the outer wheel having a holderaperture for receiving the spacer, and the spacer comprising the wheelaxle apertures.
 6. The wheeled riding toy having an engageable wave ridewheel of claim 5, wherein:a) a second rear wheel is rotatably attachedto the body; and b) the second rear wheel also comprises a wave ridewheel having an outer wheel and a spacer, the wheel having a center andat least two wheel axle apertures, at least one of said wheel axleapertures not being at the center of the wheel, the outer wheel having aholder aperture for receiving the spacer, and the spacer comprising thewheel axle apertures.
 7. The wheeled riding toy having an engageablewave ride wheel of claim 4, wherein:a) a first axle having a first and asecond axle end rotatably connects the front wheel to the front mountingarm; and b) a first and second pedal operatively connect to the firstand second axle ends respectively.
 8. The wheeled riding toy having anengageable wave ride wheel of claim 3, wherein the first rear wheel isthe wave ride wheel.
 9. The wheeled riding toy having an engageable waveride wheel of claim 8, wherein:a) a first axle having a first and secondsnap-fit end rotatably connects the first rear wheel to the body; and b)first and second snap-fit caps are snap fitted onto the first and secondsnap-fit ends respectively.
 10. The wheeled riding toy having anengageable wave ride wheel of claim 3, wherein the first and secondspacer halves each comprise a first and second spacer quarter, the firstand second spacer quarters each having at least two edge cut outs. 11.The wheeled riding toy having an engageable wave ride wheel of claim 3,wherein:a) the mounting arm has at least two axle apertures; b) thefront wheel has an axle; and c) the axle is disposed within one of theaxle apertures and disposed within one of the wheel axle apertures. 12.The wheeled riding toy having an engageable wave ride wheel of claim 3,wherein:a) the body comprises a first body end, a second body end and aback end having at least one prong back end, each prong back endreleasably connectable to the second body end; and b) at least one rearwheel rotatably attaches to at least one of the prong back ends, one ofsaid rear wheels being the first rear wheel.
 13. The wheeled riding toyhaving an engageable wave ride wheel of claim 12, wherein:a) one rearwheel rotatably attaches to the back end; b) two rear wheels rotatablyattach to a second back end; and c) the back end is interchangeable withthe second back end.
 14. A method for engaging a wheel of a wheeledriding toy having an engageable wave ride wheel, the method comprisingthe steps of:a) providing a wheeled riding toy having a body and a waveride wheel rotatably attached to the body, the wave ride wheelcomprising:i) a wheel having an outer wheel and a spacer, the wheelhaving a first and second wheel side, the wheel having a center and atleast two wheel axle apertures, at least one wheel axle aperture notbeing at the center of the wheel; ii) the spacer comprising the wheelaxle apertures and a first, second, third and fourth spacer quarters,each spacer quarter having at least two edge cut outs; iii) the outerwheel having a holder aperture on the first and second wheel sides forreceiving the first and second spacer quarters on the first wheel sideand for receiving the third and fourth spacer quarters on the secondwheel side; iv) an axle releasably placed through one of the wheel axleapertures; and v) the axle rotatably connecting the wheel to the body;b) removing the first and third spacer quarters; c) adjusting the axlefrom one edge cut out of the second and fourth spacer quarters toanother edge cut out of the second and fourth spacer quarters; and d)replacing the first and third spacer quarters into the holder aperture.15. The method of claim 14, wherein:a) there is a first and second rearwheel; b) both the first and second rear wheels comprise a wave ridewheel having:i) a wheel having a center and at least two wheel axleapertures, at least one wheel axle aperture not being at the center ofthe wheel; ii) an axle releasably placed through one of the wheel axleapertures; and iii) the axle rotatably connecting the wheel to the body;and c) the method further comprises the step of moving the axle on thesecond rear wheel from one wheel axle aperture to another wheel axleaperture.
 16. The method of claim 15, wherein:a) the axles on the firstand second rear wheels are a one-piece axle member; b) the step ofmoving the axle on the second rear wheel from one wheel axle aperture toanother wheel axle aperture comprises moving the one-piece axle memberfrom one wheel axle aperture to another wheel axle aperture on thesecond rear wheel; and c) the method further comprises the step ofmoving the one-piece axle member on the first rear wheel from one wheelaxle aperture to another wheel axle aperture on the first rear wheel.17. The method of claim 14, wherein the method further comprises thesteps of:a) removing the wave ride wheel from the body; and b) rotatablyconnecting the wave ride wheel to the body.